I just love it when y’all send in your projects, so thanks, [Kai]! But were do I even begin with this one? Okay, so, first of all, you need to know that [Kai Ruhl] built an amazing split keyboard with plenty of keys for even someone like me. Be sure to check it out, because the build log is great reading.
Image by [Kai Ruhl] via Land of KainBut that wasn’t enough — a mousing solution was in order that didn’t require taking [Kai]’s hands off of the keyboard. And so, over the course of several months, the RollerMouse Keyboard came into being. That’s the creation you see here.
Essentially, this is an ortholinear split with a built-in roller bar mouse, which basically acts like a cylindrical trackball. There’s an outer pipe that slides left/right and rolls up and down, and this sits on a stationary inner rod. The actual mouse bit is from a Logitech M-BJ69 optical number.
[Kai] found it unpleasant to work the roller bar using thumbs, so mousing is done via the palm rests. You may find it somewhat unpolished with all that exposed wiring in the middle. But I don’t. I just worry about dust is all. And like, wires getting ripped out accidentally.
There are many solutions for remote control keyboards, be they Bluetooth, infrared, or whatever else. Often they leave much to be desired, and come with distinctly underwhelming physical buttons. [konkop] has a solution to these woes we’ve not seen before, turning an ESP32-S3 into a USB HID keyboard with a web interface for typing and some physical keyboard macro buttons. Instead of typing on the thing, you connect to it via WiFi using your phone, tablet, or computer, and type into a web browser. Your typing is then relayed to the USB HID interface.
The full hardware and software for the design is in the GitHub repository. The macro buttons use Cherry MX keys, and are mapped by default to the common control sequences that most of us would find useful. The software uses Visual Studio Code, and PlatformIO.
We like this project, because it solves something we’ve all encountered at one time or another, and it does so in a novel way. Yes, typing on a smartphone screen can be just as annoying as doing so with a fiddly rubber keyboard, but at least many of us already have our smartphones to hand. Previous plug-in keyboard dongles haven’t reached this ease of use.
In 1958, the American free-market economist Leonard E Read published his famous essay I, Pencil, in which he made his point about the interconnected nature of free market economics by following everything, and we mean Everything, that went into the manufacture of the humble writing instrument.
I thought about the essay last week when I wrote a piece about a new Chinese microcontroller with an integrated driver for small motors, because a commenter asked me why I was featuring a non-American part. As a Brit I remarked that it would look a bit silly were I were to only feature parts made in dear old Blighty — yes, we do still make some semiconductors! — and it made more sense to feature cool parts wherever I found them. But it left me musing about the nature of semiconductors, and whether it’s possible for any of them to truly only come from one country. So here follows a much more functional I, Chip than Read’s original, trying to work out just where your integrated circuit really comes from. It almost certainly takes great liberties with the details of the processes involved, but the countries of manufacture and extraction are accurate.
First, There’s The Silicon
A silicon wafer, here bearing a grid of integrated circuits. Peellden, CC BY-SA 3.0.
An integrated circuit, or silicon chip, is as its name suggests, made of silicon. Silicon is all around us in rocks and minerals, as silicon dioxide, which we know in impure form as sand. The world’s largest producer of silicon metal is China, followed by Russia, then Brazil. So if China and Russia are off the table then somewhere in Brazil, a Korean-made continuous bucket excavator scoops up some sand from a quarry.
That sand is taken to a smelting plant and fed with some carbon, probably petroleum coke as a by-product from a Brazilian oil refinery, into a Taiwanese-made submerged-arc furnace. The smelting plant produces ingots of impure silicon, which are shipped to a wafer plant in Taiwan. There they pass through a German-made zone refining process to produce the ultra-pure silicon which is split into wafers. Taiwan is a global centre for semiconductor foundries so the wafers could be shipped locally, but our chip is going to be made in the USA. They’re packed in a carton made from Canadian wood pulp, and placed in a container on a Korean-made ship bound for an American port. There it’s unloaded by a German-made container handling crane, and placed on a truck for transport to the foundry. The truck is American, made in the great state of Washington.
Then, There’s The Package And Leads
Lead frames for TQFP integrated circuits. I, NobbiP, CC BY-SA 3.0.
Our integrated circuit is the chip itself, but in most cases it’s not just the bare chip. It’s supplied potted in an epoxy case, and with its contacts brought out to some kind of pins. The epoxy is a petrochemical product, while the lead frame is either stamped or chemically etched from metal sheet and plated.
So, somewhere in the Chilean Atacama desert, an American-made dragline excavator is digging out copper ore from the bottom of a huge pit. The ore is loaded into Japanese-made dump trucks, from where it’s driven to a rail head and loaded into ore carrier cars. The American-made locomotives take it to a refining plant where machinery installed by a Finnish company smelts and refines it into copper ingots. These are shipped to Sweden aboard a German-made ship, unloaded by a German-made crane, and delivered to a specialised metal refiner on a Swedish-made truck.
Meanwhile underground in Ontario, Canada, Swedish-made machinery scoops up nickel ore and loads it onto a Swedish-made mine truck. At the nickel refining plant, which is Canadian-made, the sulphur and iron impurities are removed, and the resulting nickel ingots travel by rail behind a Canadian-made (but American designed) locomotive to a port, where an American made crane loads them into an Italian-made ship bound for Sweden. Another German crane and Swedish truck deliver it to the metal refiner, where a Swedish-made plant is used to create a copper-nickel alloy.
A German-made rolling plant then turns the alloy into a thin sheet, shipped in a roll inside a container on a Japanese-made container ship bound for the USA. Eventually after another round of cranes, trains, and trucks, all American this time, it arrives at the company who makes lead frames. They use a Japanese-made machine to stamp the sheet alloy and create the frames themselves. An American-made truck delivers them to the chip foundry.
At a petrochemical plant in China, bulk epoxy resin, plasticisers, pigments, and other products are manufactured. They are supplied in drums, which are shipped on a Chinese-made container ship to an American port where American cranes and trucks do the job of delivering them to an epoxy formulation company. There they are mixed in carefully-selected proportions to produce American-made epoxy semiconductor moulding compound, which is delivered to the chip foundry on an American-made truck.
Bringing all Those Countries’ Parts Together
The foundry now has the silicon wafers, lead frames, and epoxy it needs to make an integrated circuit. There are many other chemicals used in its process, but for simplicity we’ll take those three as being the parts which make an IC. What they don’t yet have is an integrated circuit to make. For that there’s a team of high-end engineers in a smart air-conditioned office of an American semiconductor company in California. They are integrated circuit designers, but they don’t design everything. Instead they buy in much of the circuit as intellectual property, which can come from a variety of different countries. Banging the drum as a Brit I’m sure you’ll all know that ARM cores come from Cambridge here in the UK, just to name the most obvious example. So British, German, Dutch, American, and Canadian IP is combined using American software and the knowledge of American engineers, and the resulting design is sent to the foundry.
This is the Globalfoundries semiconductor plant in Dresden, Germany. Fensterblick., CC BY-SA 3.0.
The process machinery of an integrated circuit foundry lies probably at the most bleeding edge of human technology. The machines this foundry uses are mostly from Eindhoven in the Netherlands, but they are joined by American, German, Japanese, and even British ones. Even then, those machines themselves contain high-precision parts from all those countries and more, so that Dutch machine is also in part American and German too.
Whatever magic the semiconductor foundry does is performed, and at the loading bay appear cartons made from Canadian wood pulp containing reels made from Chinese bulk polymer, that have hundreds of packaged American-made integrated circuits in them. Some of them are shipped on an American truck to an airport, from where they cross the Atlantic in the hold of a pan-European-manufactured jet aircraft to be shipped from the British airport in a German-made truck to an electronics distributor in Northamptonshire. I place an order, and the next day a Polish bloke driving an American-badged van that was made in Turkey delivers a few of them to my door.
The above path from a dusty quarry in Brazil to my front door in Oxfordshire is excessively simplified, and were you to really try to find every possible global contribution it’s likely there would be few countries left out and this document would be hundreds of pages long. I hope mining engineers, metallurgists, chemists, and semiconductor process engineers will forgive me for any omissions or errors. What I hope it does illustrate though is how connected the world of manufacturing is, and how many sources come together to produce a single product. Read’s 1958 pencil is alive and well.
Although [Thomas] really likes the Raspberry Pi Pico 2 and the RP2350 MCU, he absolutely, totally, really doesn’t like the micro-USB connector on it. Hence he jumped on the opportunity to source a Pico 2 clone board with the same MCU but with a USB-C connector from AliExpress. After receiving the new board, he set about comparing the two to see whether the clone board was worth it after all. In the accompanying video you can get even more details on why you should avoid this particular clone board.
In the video the respective components of both boards are analyzed and compared to see how they stack up. The worst issues with the clone Pico 2 board are an improper USB trace impedance at 130 Ω with also a cut ground plane below it that won’t do signal integrity any favors.
There is also an issue with the buck converter routing for the RP2350 with an unconnected pin (VREG_FB) despite the recommended layout in the RP2350 datasheet. Power supply issues continue with the used LN3440 DC-DC converter which can source 800 mA instead of the 1A of the Pico 2 version and performed rather poorly during load tests, with one board dying at 800 mA load.
Do you remember Nokia phones, with their Symbian OS? Dead and gone, you might think, but even they have dedicated enthusiasts here in 2026. Some of them have gone so far as to produce a new ROM for the daddy of Symbian phones, the Nokia N8, and [Janus Cycle] is giving it a spin.
For many people, the smartphone era began when the first Apple iPhones and Android devices reached the market, but the smartphone itself can be traced back almost two decades earlier to an IBM device. In the few years before the birth of today’s platforms many people even had smartphones without quite realizing what they had, because Nokia, the market leader in the 2000s, failed to make their Symbian platform user friendly in the way that Apple did. The N8 was their attempt to produce an iPhone competitor, but its lack of an on-device app store and that horrific Windows-based installation system meant it would be their last mass-market flagship before falling down the Microsoft Windows Phone rabbit hole.
In the video below the break he takes a pair of N8s and assembles one with that beautiful camera fully working, before installing the new ROM and giving it a spin. We get to see at last what the N8 could have been but wasn’t, as it gains the last Symbian release from Nokia, and the crucial missing app store. Even fifteen years later it’s a very slick device, enough to make us sorry that this ROM won’t be made for the earlier N-series sitting in a drawer where this is being written. We salute its developers for keeping the N8 alive.
The Commodore VIC-20 was a solid microcomputer that paved the way for the legendary Commodore 64 to come. If you’re a fan of the machine and want to revisit its glory days, you could hunt one down on an auction site and hope that it’s in working order. Or you could just emulate the VIC-20 in your browser thanks to the work of [Lance Ewing].
The project is called JVic—because it’s a VIC-20 emulator written in Java. It’s primarily intended for playing old VIC-20 games, and is designed with mobile devices front of mind—so it works well on a phone screen. You can enjoy the built-in library of games, or you can even direct JVic to boot up a ROM from a ZIP file hosted on a given URL or attached to a forum post. You can also install it on your own device rather than running it online, if so desired. [Lance] provides a range of setup options for running it locally or putting it on your own web server if that’s how you like to do things. Files are on Github for those eager to dive in.
We get lots of VIC-20 hacks around these parts. Even if it’s not the most popular machine that Commodore ever built, it’s certainly up there in the rankings. If you want to learn Forth, or even build a VIC-20 from scratch, we’ve explored that before. If you’ve got your own retrocomputer hacks kicking around, don’t hesitate to let us know!
Very-long baseline interferometry (VLBI) is a technique in radio astronomy whereby multiple radio telescopes cooperate to bundle their received data and in effect create a much larger singular radio telescope. For this to work it is however essential to have exact timing and other relevant information to accurately match the signals from each individual radio telescope. As VLBI is used for increasingly higher ranges and bandwidths this makes synchronizing the signals much harder, but an optical frequency comb technique may offer a solution here.
In the paper by [Minji Hyun] et al. it’s detailed how they built the system and used it with the Korean VLBI Network (VLB) Yonsei radio telescope in Seoul as a proof of concept. This still uses the same hydrogen maser atomic clock as timing source, but with the optical transmission of the pulses a higher accuracy can be achieved, limited only by the photodiode on the receiving end.
In the demonstration up to 50 GHz was possible, but commercial 100 GHz photodiodes are available. It’s also possible to send additional signals via the fiber on different wavelengths for further functionality, all with the ultimately goal of better timing and adjustment for e.g. atmospheric fluctuations that can affect radio observations.
